JP2018206339A - Computer-implemented method, program and information processor for providing virtual space - Google Patents

Abstract

To provide techniques capable of reducing VR sickness in a virtual space.SOLUTION: When an object 901 moves, a computer displays a field-of-view image 1002 after a field-of-view image 1001. The field-of-view image 1002 includes a trajectory object 910 representing a movement path of the object 901. Then, the computer displays a field-of-view image 1003. The field-of-view image 1003 does not contain any object corresponding to the object 901. That is, when the object 901 moves out of the field-of-view image 1001, the computer displays the field-of-view image 1002 containing the trajectory object 910 before displaying the field-of-view image 1003 not containing the object 901.SELECTED DRAWING: Figure 1

Description

  This disclosure relates to a technique for providing a virtual space, and more particularly to a technique for providing a virtual space including a moving object.

  A technique for providing virtual reality using a head-mounted device (HMD) device is known. For example, Japanese Patent Laying-Open No. 2006-218774 (Patent Document 1) discloses a technique for moving an object in a virtual space by a player's operation.

JP, 2006-218774, A

  Unlike the real space, the object can instantaneously move to a relatively far position in the virtual space. On the other hand, a user observing such an object may feel a so-called VR (Virtual Reality) sickness due to a sense of discomfort with respect to a sudden change in the position of the object. Therefore, there is a need for a technique for reducing VR sickness felt by the user.

  An object of one aspect of the present disclosure is to provide a technique capable of reducing VR sickness in a virtual space.

  According to certain embodiments, a computer-implemented method connected to a plurality of head mounted devices to provide a virtual space is provided. A method defines a virtual space, and a first avatar object corresponding to a user of a first head mounted device and a second corresponding to a user of a second head mounted device of the plurality of head mounted devices. Arranging the avatar object in the virtual space, presenting an image corresponding to the position of the first avatar object in the virtual space to the first head mounted device, and an operation for moving the second avatar object And presenting a trajectory object representing the movement path of the second avatar object to the first head mounted device based on.

It is a figure for demonstrating the change in the visual field image at the time of the movement of an object. It is a figure for demonstrating typically the aspect of provision of the virtual space to each user by a chat system. It is a figure showing the outline of a structure of the HMD (Head-Mounted Device) system 100 according to a certain embodiment. It is a block diagram showing an example of the hardware constitutions of the computer 200 according to one situation. It is a figure which represents notionally the uvw visual field coordinate system set to HMD110 according to an embodiment. It is a figure which represents notionally the one aspect | mode which represents the virtual space 2 according to a certain embodiment. It is the figure showing the head of user 190 wearing HMD110 according to a certain embodiment from the top. It is a figure showing the YZ cross section which looked at the visual recognition area 23 from the X direction in the virtual space 2. It is a figure showing XZ section which looked at visual recognition field 23 from the Y direction in virtual space 2. It is a figure showing schematic structure of the controller 160 according to a certain embodiment. FIG. 10 is a diagram showing an example of a hand object 810 arranged in a virtual space corresponding to the right hand of a user 190 holding the right controller 800. FIG. 3 is a block diagram showing a computer 200 according to an embodiment as a module configuration. It is a sequence chart showing a part of process performed in the HMD system 100 according to an embodiment. FIG. 10 is a diagram showing an aspect of storing chat monitor information in the memory module 240. FIG. 3 is a diagram illustrating an aspect of storing object information in a memory module 240. It is a figure for demonstrating an example of the aspect from which the relative position of a virtual camera and an object changes. It is a figure for demonstrating the other example of the aspect from which the relative position of a virtual camera and an object changes. FIG. 18 is a diagram illustrating a change in the field-of-view image according to a change in the relative position of the virtual camera 1 and the object 901 illustrated in FIG. It is a figure for demonstrating the production | generation of a locus | trajectory object. It is a figure for demonstrating the production | generation of a locus | trajectory object. It is a figure for demonstrating the production | generation of a locus | trajectory object. It is a flowchart of the process for displaying the complementary image which a processor performs.

  Embodiments of a computer that provides a virtual space will be described below with reference to the drawings. In the following description, the same parts and components are denoted by the same reference numerals. Their names and functions are also the same. Therefore, these descriptions will not be repeated.

<1. Summary of disclosure>
With reference to FIG. 1, the display of a complementary image when an object moves in a virtual space will be described. In the present embodiment, the complementary image refers to an image that displays an image (trajectory object) representing a trajectory of a moving object. FIG. 1 is a diagram for explaining changes in the view field image when the object moves, and includes view field images 1001, 1002, and 1003. FIG.

  Referring to FIG. 1, the computer first displays a view field image 1001. The view image 1001 includes an object 901 together with the objects 1110 and 1120. The object 1110 is an object representing a table, for example. The object 1120 is an object representing a screen, for example. The object 901 is, for example, an avatar object corresponding to a user different from the HMD user who displays the view field image 1001.

  Next, the computer displays a view image 1002 next to the view image 1001. The view image 1002 includes a trajectory object 910. The view image 1002 is an example of a complementary image.

  The trajectory object 910 represents, for example, an elastic body that extends from the position of the object 901 in the view field image 1001. In the example of FIG. 1, the object 901 moves to the left at the next time after the view image 1001 is displayed. Corresponding to this, the trajectory object 910 represents an elastic body extending from right to left.

  The right end position of the trajectory object 910 in the view field image 1002 corresponds to the position of the object 901 in the view field image 1001. As long as the trajectory object 910 represents the movement path of the object 901 as will be described later, the position of the end of the trajectory object 910 is not limited to the position of the object 901.

  Thereafter, the computer displays a view field image 1003. The view image 1003 does not include the object 901.

  As described with reference to FIG. 1, when the object 901 in the view image 1001 moves outside the view image 1001, the computer displays the trajectory object 910 before displaying the view image 1003 that does not include the object 901. A view field image 1002 including is displayed.

<2. Overview of chat system>
In the present embodiment, a chat system is an example of the provided virtual space.

  FIG. 2 is a diagram for schematically explaining how the virtual space is provided to each user by the chat system. As shown in FIG. 2, chat system 1000 includes a computer 200A and a computer 200B. The computer 200A provides a virtual space image 22A. The computer 200B provides a virtual space image 22B.

  The computer 200A is connected to a head mounted device (HMD) 110A. The HMD 110A places a virtual camera at a position corresponding to the state of the user 190A of the HMD 110A, and displays a view field image according to the line of sight of the virtual camera on the monitor 112A. The monitor 112A is an example of a display that displays a view field image.

  The computer 200B is connected to the HMD 110B. The HMD 110B places a virtual camera at a position corresponding to the state of the user 190B of the HMD 110B, and displays a view field image according to the line of sight of the virtual camera on the monitor 112B.

  The computer 200A and the computer 200B can display the same virtual space image. In the virtual space, an avatar object corresponding to the user 190A and an avatar object corresponding to the user 190B may be arranged. Thereby, user 190A and user 190B can visually recognize the object corresponding to the other user in the same virtual space (for example, a space representing a virtual chat room). In one embodiment, the field-of-view image displayed by the computer 200A is obtained by cutting out a range of images according to the orientation of the user of the HMD 110A from the virtual space image. In one embodiment, the field-of-view image displayed by the computer 200B is obtained by cutting out a range of images according to the orientation of the user of the HMD 110B from the virtual space image.

  The computers 200 </ b> A and 200 </ b> B are connected to the server 150 via the network 19. The server 150 acquires the behavior of the users 190A and 190B of the HMDs 110A and 110B via the computers 200A and 200B, and shares the behavior of each user with the computers 200A and 200B. Thereby, the computers 200A and 200B can provide a chat system in which the behavior of each user is reflected.

  More specifically, the computer 200A provides a chat system that reflects not only the behavior of the user 190A but also the behavior of the user 190B who is the user of the computer 200B. The field-of-view image representing the chat system displays an avatar object corresponding to the user 190B. For example, the view image 1001 of FIG. 1 is provided by the computer 200A. An object 901 in the view field image 1001 corresponds to the user 190B.

  In this specification, when referring to the common properties of the computer 200A and the computer 200B, they may be referred to as “computer 200”. Further, when referring to the common properties of the HMD 110A and the HMD 110B, they may be referred to as “HMD 110”.

  In this specification, a system including the computer 200 and the HMD 110 may be referred to as an “HMD system”.

<3. HMD system>
The configuration of the HMD system 100 will be described with reference to FIG. FIG. 3 is a diagram representing a schematic configuration of HMD system 100 according to an embodiment. In one aspect, the HMD system 100 is provided as a home system or a business system.

  The HMD system 100 can communicate with other HMD systems 100A and 100B at remote locations via the network 19. HMD system 100A may be used by user 190A. HMD 100B may be used by user 190B. The configuration of the HMD systems 100A and 100B is the same as the configuration of the HMD system 100. Constituent elements similar to those of the HMD system 100 are denoted by reference signs A and B. Accordingly, each HMD system will be described below with reference to the configuration of the HMD system 100 as appropriate.

  The HMD system 100 includes an HMD 110, an HMD sensor 120, a controller 160, and a computer 200. The HMD 110 includes a monitor 112, a speaker 115, a microphone 119, and a gaze sensor 140. The controller 160 can include a motion sensor 130.

  In one aspect, the computer 200 can be connected to the Internet and other networks 19, and can communicate with the server 150, the computers 200 </ b> A, 200 </ b> B, and other computers connected to the network 19. In other aspects, the HMD 110 may include a sensor 114 instead of the HMD sensor 120.

  The HMD 110 may be worn on the head of the user 190 and provide a virtual space to the user 190 during operation. More specifically, the HMD 110 displays a right-eye image and a left-eye image on the monitor 112, respectively. When each eye of the user 190 visually recognizes each image, the user 190 can recognize the image as a three-dimensional image based on the parallax of both eyes.

  The monitor 112 is realized as a non-transmissive display device, for example. In one aspect, the monitor 112 is disposed on the main body of the HMD 110 so as to be positioned in front of both eyes of the user 190. Therefore, when the user 190 visually recognizes the three-dimensional image displayed on the monitor 112, the user 190 can be immersed in the virtual space. In one embodiment, the virtual space includes, for example, a background, an object that can be operated by the user 190, and an image of a menu that can be selected by the user 190.

  In one aspect, the computers 200, 200A, and 200B communicate signals with other computers based on the operations of the respective users 190, 190A, and 190B. For example, the computer 200 generates a video signal for providing a virtual space, and transmits the video signal to the HMD 110. When the HMD 110 transmits the video signal to the monitor 112, the monitor 112 displays a virtual space image based on the received video signal. The other computer and the HMD connected to the computer are the same as those of the computer 200 and the HMD 110.

  Each of the HMD systems 100A and 100B has the same configuration as the HMD system 100. That is, each of the HMD systems 100A and 100B includes HMDs 110A and 110B, HMD sensors 120A and 120B, controllers 160A and 160B, and computers 200A and 200B. Each of the HMDs 110A and 110B includes monitors 112A and 112B, speakers 115A and 115B, microphones 119A and 119B, and gaze sensors 140A and 140B, respectively. Each of the controllers 160A and 160B may include each of the motion sensors 130A and 130B. Each of the HMDs 110A and 110B may include sensors 114A and 114B.

  In one embodiment, when the computers 200, 200A, and 200B are executing a VR (Virtual Reality) chat application for communicating via a virtual space, the computers 200, 200A, and 200B are connected to the HMDs 110, 110A, Communication through the virtual space presented by 110B is realized. In communication via a virtual space, video and audio are communicated. At this time, an avatar object corresponding to each user is presented in the virtual space. For example, when the user 190 is communicating with the other users 190A and 190B, the HMD 110 worn by the user 190 presents an avatar object corresponding to the users 190A and 190B. The user 190 can communicate with other users 190A and 190B via the avatar object while being immersed in the virtual space.

  In an embodiment, the monitor 112 may be realized as a liquid crystal monitor or an organic EL (Electro Luminescence) monitor provided in a so-called smartphone or other information display terminal.

  In one aspect, the monitor 112 may include a sub-monitor for displaying an image for the right eye and a sub-monitor for displaying an image for the left eye. In another aspect, the monitor 112 may be configured to display a right-eye image and a left-eye image integrally. In this case, the monitor 112 includes a high-speed shutter. The high-speed shutter operates so that an image for the right eye and an image for the left eye can be displayed alternately so that the image is recognized only by one of the eyes.

  The gaze sensor 140 detects a direction (gaze direction) in which the gaze of the right eye and the left eye of the user 190 is directed. The detection of the direction is realized by, for example, a known eye tracking function. The gaze sensor 140 is realized by a sensor having the eye tracking function. In one aspect, the gaze sensor 140 preferably includes a right eye sensor and a left eye sensor. The gaze sensor 140 may be, for example, a sensor that irradiates the right eye and the left eye of the user 190 with infrared light and detects the rotation angle of each eyeball by receiving reflected light from the cornea and iris with respect to the irradiated light. . The gaze sensor 140 can detect the line-of-sight direction of the user 190 based on each detected rotation angle.

  The speaker 115 outputs a sound (speech) corresponding to the sound data received from the computer 200 to the outside. The microphone 119 outputs an audio signal corresponding to the utterance of the user 190 to the computer 200. The user 190 can speak to the other users 190 </ b> A and 190 </ b> B using the microphone 119, and can listen to the speech of the other users 190 </ b> A and 190 </ b> B using the speaker 115.

  The HMD sensor 120 includes a plurality of light sources (not shown). Each light source is realized by, for example, an LED (Light Emitting Diode) that emits infrared rays. The HMD sensor 120 has a position tracking function for detecting the movement of the HMD 110. Using this function, the HMD sensor 120 detects the position and inclination of the HMD 110 in the real space.

  In other aspects, HMD sensor 120 may be realized by a camera. In this case, the HMD sensor 120 can detect the position and inclination of the HMD 110 by executing image analysis processing using image information of the HMD 110 output from the camera.

  In another aspect, the HMD 110 may include a sensor 114 instead of the HMD sensor 120 as a position detector. The HMD 110 can detect the position and inclination of the HMD 110 itself using the sensor 114. For example, when the sensor 114 is an angular velocity sensor, a geomagnetic sensor, an acceleration sensor, a gyro sensor, or the like, the HMD 110 uses any of these sensors in place of the HMD sensor 120 to determine its position and inclination. It can be detected. As an example, when the sensor 114 is an angular velocity sensor, the angular velocity sensor detects angular velocities around the three axes of the HMD 110 in real space over time. The HMD 110 calculates a temporal change in the angle around the three axes of the HMD 110 based on each angular velocity, and further calculates an inclination of the HMD 110 based on the temporal change in the angle.

  The HMD 110 may include a transmissive display device. In this case, the transmissive display device may be temporarily configured as a non-transmissive display device by adjusting the transmittance. Further, the visual field image may include a configuration for presenting the real space in a part of the image configuring the virtual space. For example, an image captured by a camera mounted on the HMD 110 may be displayed so as to be superimposed on a part of the field-of-view image. Real space may be visible from a part.

  Server 150 may send a program to computer 200. In other aspects, the server 150 may communicate with other computers 200 for providing virtual reality to the HMD 110 used by other users. For example, when a plurality of users play a participatory game in an amusement facility, each computer 200 communicates a signal based on each user's operation with another computer 200, and a plurality of users interact in the same virtual space ( VR chat) can be enjoyed.

  The controller 160 receives input of commands from the user 190 to the computer 200. In one aspect, the controller 160 is configured to be gripped by the user 190. In another aspect, the controller 160 is configured to be attachable to the body of the user 190 or a part of clothing. In another aspect, the controller 160 may be configured to output at least one of vibration, sound, and light based on a signal sent from the computer 200. In another aspect, the controller 160 accepts an operation given by the user 190 to control the position and movement of an object arranged in a space that provides virtual reality.

  In one aspect, the motion sensor 130 is attached to the hand of the user 190 and detects the movement of the user 190 hand. For example, the motion sensor 130 detects the rotation speed, the number of rotations, and the like of the hand. Data indicating the detection result of the hand movement of the user 190 obtained by the motion sensor 130 is sent to the computer 200. The motion sensor 130 is provided in a glove-type controller 160, for example. In some embodiments, for safety in real space, it is desirable that the controller 160 be mounted on something that does not fly easily by being mounted on the hand of the user 190, such as a glove shape. In another aspect, a sensor that is not worn by the user 190 may detect the movement of the hand of the user 190. For example, a signal from a camera that captures the user 190 may be input to the computer 200 as a signal representing the operation of the user 190. The motion sensor 130 and the computer 200 are connected to each other by wire or wirelessly. In the case of wireless, the communication mode is not particularly limited, and for example, Bluetooth (registered trademark) or other known communication methods are used.

  In another aspect, the HMD system 100 may include a television broadcast receiving tuner. According to such a configuration, the HMD system 100 can display a television program in the virtual space 2.

  In still another aspect, the HMD system 100 may include a communication circuit for connecting to the Internet or a call function for connecting to a telephone line.

  More specifically, in one aspect, the user 190 can select a communication partner (hereinafter also referred to as “chat partner”) by using a controller or by selecting an avatar object desired to be communicated with the line of sight. Hereinafter, a case where the user 190A is selected as a chat partner will be described. The chat partner is not limited to one person, and two or more may be selected.

  After the user 190 selects the user 190 </ b> A and speaks into the microphone 119, a sound signal based on the sound is transmitted to the computer 200. The gaze sensor 140 detects the movement of the line of sight of the user 190. The detection result is sent to the computer 200 as eye tracking data. The computer 200 transmits audio data and eye tracking data based on the received audio signal to the user 190A. For example, the computer 200 transmits audio data and eye tracking data to the server 150 via the network 19. Each of the voice data and the eye tracking data includes a network address of the computer 200A used by the user 190A. The server 150 transmits the audio data and eye tracking data received from the computer 200 to the computer 200A via the network 19, respectively. Note that the timing at which the audio data and the eye tracking data are received by the computer 200A is not always the same, and one of the data may be delayed from the other data.

  The computer 200A outputs the audio data received from the server 150 to the speaker 115 of the HMD 110A worn by the user 190A. The computer 200 </ b> A generates data for changing the line of sight of the user 190 avatar object based on the received eye tracking data, and transmits the data to the monitor 112. The user 190A can hear the voice of the user 190 via the speaker 115 of the HMD 110A and can visually recognize the avatar object presented on the monitor 112.

  When the user 190A speaks to the user 190, voice data and eye tracking data are transmitted from the computer 200A to the computer 200 in the same manner as described above. In this manner, the user 190 and the user 190A can interact in the virtual space using each avatar object.

  Next, the configuration of the server 150 will be described. As shown in FIG. 3, it is a block diagram illustrating an example of a hardware configuration of server 150 according to one aspect. The server 150 includes a processor 151, a memory 152, and a communication interface 153 as main components.

  The processor 151 executes a series of instructions included in the program stored in the memory 152 based on a signal given to the server 150 or when a predetermined condition is satisfied. In one aspect, the processor 151 is realized as a CPU, MPU, FPGA, or other device.

  The memory 152 stores programs and data. The program is executed by the processor 151, for example. The data includes data input to the server 150 and data generated by the processor 151.

  The memory 152 includes volatile memory and / or nonvolatile memory. The memory 152 may include a storage device that permanently retains programs and data. In this case, the memory 152 is realized as, for example, a ROM, a hard disk device, a flash memory, or another nonvolatile storage device. The program stored in the memory 152 includes a program for adjusting the virtual space provided in each HMD system 100 of the chat system according to the input in the other HMD system 100. The memory 152 includes a chat information storage unit 152A for storing chat monitor information and object information described later.

  The communication interface 153 communicates with another computer (for example, the computer 200) via the network 19. In one aspect, the communication interface 153 is implemented as, for example, a LAN or other wired communication interface, or a wireless communication interface such as WiFi, Bluetooth (registered trademark), NFC, or the like. However, the communication interface 153 is not limited to the above.

[Hardware configuration]
A computer 200 according to the present embodiment will be described with reference to FIG. FIG. 4 is a block diagram illustrating an example of a hardware configuration of computer 200 according to one aspect. The computer 200 includes a processor 10, a memory 11, a storage 12, an input / output interface 13, and a communication interface 14 as main components. Each component is connected to the bus 15.

  The processor 10 executes a series of instructions included in the program stored in the memory 11 or the storage 12 based on a signal given to the computer 200 or based on the establishment of a predetermined condition. In one aspect, the processor 10 is realized as a CPU (Central Processing Unit), an MPU (Micro Processor Unit), an FPGA (Field-Programmable Gate Array), or other device.

  The memory 11 temporarily stores programs and data. The program is loaded from the storage 12, for example. The data includes data input to the computer 200 and data generated by the processor 10. In one aspect, the memory 11 is realized as a RAM (Random Access Memory) or other volatile memory.

  The storage 12 holds programs and data permanently. The storage 12 is realized, for example, as a ROM (Read-Only Memory), a hard disk device, a flash memory, or other nonvolatile storage device. The programs stored in the storage 12 include a program for providing a virtual space in the HMD system 100, a simulation program, a game program, a user authentication program, and a program for realizing communication with another computer 200. The data stored in the storage 12 includes data and objects for defining the virtual space.

  In another aspect, the storage 12 may be realized as a removable storage device such as a memory card. In still another aspect, a configuration using a program and data stored in an external storage device may be used instead of the storage 12 built in the computer 200. According to such a configuration, for example, in a scene where a plurality of HMD systems 100 are used like an amusement facility, it is possible to update programs and data collectively.

  In some embodiments, the input / output interface 13 communicates signals with the HMD 110, HMD sensor 120, or motion sensor 130. In one aspect, the input / output interface 13 is realized using a USB (Universal Serial Bus) interface, a DVI (Digital Visual Interface), an HMDI (registered trademark) (High-Definition Multimedia Interface), or other terminals. The input / output interface 13 is not limited to that described above.

  In certain embodiments, the input / output interface 13 may further communicate with the controller 160. For example, the input / output interface 13 receives a signal output from the motion sensor 130. In another aspect, the input / output interface 13 sends the instruction output from the processor 10 to the controller 160. This command instructs the controller 160 to vibrate, output sound, emit light, and the like. When the controller 160 receives the command, the controller 160 executes vibration, sound output, or light emission according to the command.

  The communication interface 14 is connected to the network 19 and communicates with other computers (for example, the server 150 and the computers 200A and 200B) connected to the network 19. In one aspect, the communication interface 14 is implemented as, for example, a local area network (LAN) or other wired communication interface, or a wireless communication interface such as WiFi (Wireless Fidelity), Bluetooth (registered trademark), NFC (Near Field Communication), or the like. Is done. The communication interface 14 is not limited to the above.

  In one aspect, the processor 10 accesses the storage 12, loads one or more programs stored in the storage 12 into the memory 11, and executes a series of instructions included in the program. The one or more programs include an operating system of the computer 200, an application program for providing a virtual space, software for realizing a remote conference connecting remote locations, and game software that can be executed in the virtual space using the controller 160 And so on. The processor 10 sends a signal for providing a virtual space to the HMD 110 via the input / output interface 13. The HMD 110 displays an image on the monitor 112 based on the signal.

  In the example illustrated in FIG. 4, the computer 200 is configured to be provided outside the HMD 110. However, in another aspect, the computer 200 may be incorporated in the HMD 110. As an example, a portable information communication terminal (for example, a smartphone) including the monitor 112 may function as the computer 200.

  Further, the computer 200 may be configured to be used in common for a plurality of HMDs 110. According to such a configuration, for example, the same virtual space can be provided to a plurality of users, so that each user can enjoy the same application as other users in the same virtual space.

  In an embodiment, in the HMD system 100, a global coordinate system is set in advance. The global coordinate system has three reference directions (axes) parallel to the vertical direction in the real space, the horizontal direction orthogonal to the vertical direction, and the front-rear direction orthogonal to both the vertical direction and the horizontal direction. In the present embodiment, the global coordinate system is one of the viewpoint coordinate systems. Therefore, the horizontal direction, the vertical direction (up-down direction), and the front-rear direction in the global coordinate system are defined as an x axis, a y axis, and a z axis, respectively. More specifically, in the global coordinate system, the x axis is parallel to the horizontal direction of the real space. The y axis is parallel to the vertical direction of the real space. The z axis is parallel to the front-rear direction of the real space.

  In one aspect, HMD sensor 120 includes an infrared sensor. When the infrared sensor detects the infrared rays emitted from each light source of the HMD 110, the presence of the HMD 110 is detected. The HMD sensor 120 further detects the position and inclination of the HMD 110 in the real space according to the movement of the user 190 wearing the HMD 110 based on the value of each point (each coordinate value in the global coordinate system). More specifically, the HMD sensor 120 can detect temporal changes in the position and inclination of the HMD 110 using each value detected over time.

  The global coordinate system is parallel to the real space coordinate system. Therefore, each inclination of the HMD 110 detected by the HMD sensor 120 corresponds to each inclination around the three axes of the HMD 110 in the global coordinate system. The HMD sensor 120 sets the uvw visual field coordinate system to the HMD 110 based on the inclination of the HMD 110 in the global coordinate system. The uvw visual field coordinate system set in the HMD 110 corresponds to a viewpoint coordinate system when the user 190 wearing the HMD 110 views an object in the virtual space.

[Uvw visual field coordinate system]
The uvw visual field coordinate system will be described with reference to FIG. FIG. 5 is a diagram conceptually showing a uvw visual field coordinate system set in HMD 110 according to an embodiment. The HMD sensor 120 detects the position and inclination of the HMD 110 in the global coordinate system when the HMD 110 is activated. The processor 10 sets the uvw visual field coordinate system to the HMD 110 based on the detected value.

  As shown in FIG. 5, the HMD 110 sets a three-dimensional uvw visual field coordinate system with the head (origin) of the user wearing the HMD 110 as the center (origin). More specifically, the HMD 110 includes a horizontal direction, a vertical direction, and a front-rear direction (x-axis, y-axis, z-axis) that define the global coordinate system by an inclination around each axis of the HMD 110 in the global coordinate system. Three directions newly obtained by tilting around the axis are set as the pitch direction (u-axis), yaw direction (v-axis), and roll direction (w-axis) of the uvw visual field coordinate system in the HMD 110.

  In a certain situation, when the user 190 wearing the HMD 110 stands upright and is viewing the front, the processor 10 sets the uvw visual field coordinate system parallel to the global coordinate system to the HMD 110. In this case, the horizontal direction (x-axis), vertical direction (y-axis), and front-back direction (z-axis) in the global coordinate system are the pitch direction (u-axis) and yaw direction (v-axis) of the uvw visual field coordinate system in the HMD 110. , And the roll direction (w axis).

  After the uvw visual field coordinate system is set to the HMD 110, the HMD sensor 120 can detect the inclination (the amount of change in inclination) of the HMD 110 in the set uvw visual field coordinate system based on the movement of the HMD 110. In this case, the HMD sensor 120 detects the pitch angle (θu), yaw angle (θv), and roll angle (θw) of the HMD 110 in the uvw visual field coordinate system as the inclination of the HMD 110. The pitch angle (θu) represents the inclination angle of the HMD 110 around the pitch direction in the uvw visual field coordinate system. The yaw angle (θv) represents the inclination angle of the HMD 110 around the yaw direction in the uvw visual field coordinate system. The roll angle (θw) represents the inclination angle of the HMD 110 around the roll direction in the uvw visual field coordinate system.

  The HMD sensor 120 sets the uvw visual field coordinate system in the HMD 110 after the HMD 110 has moved to the HMD 110 based on the detected tilt angle of the HMD 110. The relationship between the HMD 110 and the uvw visual field coordinate system of the HMD 110 is always constant regardless of the position and inclination of the HMD 110. When the position and inclination of the HMD 110 change, the position and inclination of the uvw visual field coordinate system of the HMD 110 in the global coordinate system change in conjunction with the change of the position and inclination.

  In one aspect, the HMD sensor 120 is based on the infrared light intensity acquired based on the output from the infrared sensor and the relative positional relationship between a plurality of points (for example, the distance between the points). The position in the real space may be specified as a relative position to the HMD sensor 120. Further, the processor 10 may determine the origin of the uvw visual field coordinate system of the HMD 110 in the real space (global coordinate system) based on the specified relative position.

[Virtual space]
The virtual space will be further described with reference to FIG. FIG. 6 is a diagram conceptually showing one aspect of expressing virtual space 2 according to an embodiment. The virtual space 2 has a spherical structure that covers the entire 360 ° direction of the center 21. In FIG. 6, the upper half of the celestial sphere in the virtual space 2 is illustrated for the sake of simplicity. In the virtual space 2, each mesh is defined. The position of each mesh is defined in advance as coordinate values in the XYZ coordinate system defined in the virtual space 2. The computer 200 associates each partial image constituting content (still image, moving image, etc.) that can be developed in the virtual space 2 with each corresponding mesh in the virtual space 2, and the virtual space image 22 that can be visually recognized by the user. Is provided to the user.

  In one aspect, the virtual space 2 defines an XYZ coordinate system with the center 21 as the origin. The XYZ coordinate system is, for example, parallel to the global coordinate system. Since the XYZ coordinate system is a kind of viewpoint coordinate system, the horizontal direction, vertical direction (vertical direction), and front-rear direction in the XYZ coordinate system are defined as an X axis, a Y axis, and a Z axis, respectively. Therefore, the X axis (horizontal direction) of the XYZ coordinate system is parallel to the x axis of the global coordinate system, the Y axis (vertical direction) of the XYZ coordinate system is parallel to the y axis of the global coordinate system, and The Z axis (front-rear direction) is parallel to the z axis of the global coordinate system.

  When the HMD 110 is activated, that is, in the initial state of the HMD 110, the virtual camera 1 is disposed at the center 21 of the virtual space 2. The virtual camera 1 similarly moves in the virtual space 2 in conjunction with the movement of the HMD 110 in the real space. Thereby, changes in the position and orientation of the HMD 110 in the real space are similarly reproduced in the virtual space 2.

  As with the HMD 110, the uvw visual field coordinate system is defined for the virtual camera 1. The uvw visual field coordinate system of the virtual camera in the virtual space 2 is defined so as to be linked to the uvw visual field coordinate system of the HMD 110 in the real space (global coordinate system). Therefore, when the inclination of the HMD 110 changes, the inclination of the virtual camera 1 also changes accordingly. The virtual camera 1 can also move in the virtual space 2 in conjunction with the movement of the user wearing the HMD 110 in the real space.

  Since the orientation of the virtual camera 1 is determined according to the position and inclination of the virtual camera 1, the reference line of sight (reference line of sight 5) when the user visually recognizes the virtual space image 22 depends on the orientation of the virtual camera 1. Determined. The processor 10 of the computer 200 defines the visual recognition area 23 in the virtual space 2 based on the reference visual line 5. The visual recognition area 23 corresponds to the visual field of the user wearing the HMD 110 in the virtual space 2.

  The gaze direction of the user 190 detected by the gaze sensor 140 is a direction in the viewpoint coordinate system when the user 190 visually recognizes the object. The uvw visual field coordinate system of the HMD 110 is equal to the viewpoint coordinate system when the user 190 visually recognizes the monitor 112. Further, the uvw visual field coordinate system of the virtual camera 1 is linked to the uvw visual field coordinate system of the HMD 110. Therefore, the HMD system 100 according to a certain aspect can regard the line-of-sight direction of the user 190 detected by the gaze sensor 140 as the line-of-sight direction of the user in the uvw visual field coordinate system of the virtual camera 1.

[User's line of sight]
With reference to FIG. 7, the determination of the user's line-of-sight direction will be described. FIG. 7 is a top view of the head of user 190 wearing HMD 110 according to an embodiment.

  In one aspect, gaze sensor 140 detects each line of sight of user 190's right eye and left eye. In a certain aspect, when the user 190 is looking near, the gaze sensor 140 detects the lines of sight R1 and L1. In another aspect, when the user 190 is looking far away, the gaze sensor 140 detects the lines of sight R2 and L2. In this case, the angle formed by the lines of sight R2 and L2 with respect to the roll direction w is smaller than the angle formed by the lines of sight R1 and L1 with respect to the roll direction w. The gaze sensor 140 transmits the detection result to the computer 200.

  When the computer 200 receives the detection values of the lines of sight R1 and L1 from the gaze sensor 140 as the line-of-sight detection result, the computer 200 identifies the point of sight N1 that is the intersection of the lines of sight R1 and L1 based on the detection value. On the other hand, when the detected values of the lines of sight R2 and L2 are received from the gaze sensor 140, the computer 200 specifies the intersection of the lines of sight R2 and L2 as the point of sight. The computer 200 specifies the line-of-sight direction N0 of the user 190 based on the specified position of the gazing point N1. For example, the computer 200 detects the direction in which the straight line passing through the midpoint of the straight line connecting the right eye R and the left eye L of the user 190 and the gazing point N1 extends as the line-of-sight direction N0. The line-of-sight direction N0 is a direction in which the user 190 is actually pointing the line of sight with both eyes. The line-of-sight direction N0 corresponds to the direction in which the user 190 actually directs the line of sight with respect to the visual recognition area 23.

  In another aspect, the HMD system 100 may include a microphone and a speaker in any part constituting the HMD system 100. The user can give a voice instruction to the virtual space 2 by speaking to the microphone.

  In another aspect, HMD system 100 may include a television broadcast receiving tuner. According to such a configuration, the HMD system 100 can display a television program in the virtual space 2.

  In still another aspect, the HMD system 100 may include a communication circuit for connecting to the Internet or a call function for connecting to a telephone line.

[Visibility area]
The visual recognition area 23 will be described with reference to FIGS. 8 and 9. FIG. 8 is a diagram illustrating a YZ cross section of the visual recognition area 23 viewed from the X direction in the virtual space 2. FIG. 9 is a diagram illustrating an XZ cross section of the visual recognition area 23 viewed from the Y direction in the virtual space 2.

  As shown in FIG. 8, the visual recognition area 23 in the YZ cross section includes an area 24. The region 24 is defined by the reference line of sight 5 of the virtual camera 1 and the YZ cross section of the virtual space 2. The processor 10 defines a range including the polar angle α around the reference line of sight 5 in the virtual space as the region 24.

  As shown in FIG. 9, the visual recognition area 23 in the XZ cross section includes an area 25. The region 25 is defined by the reference line of sight 5 and the XZ cross section of the virtual space 2. The processor 10 defines a range including the azimuth angle β around the reference line of sight 5 in the virtual space 2 as a region 25.

  In one aspect, the HMD system 100 provides the virtual space to the user 190 by displaying the view image 26 on the monitor 112 based on a signal from the computer 200. The view image 26 corresponds to a portion of the virtual space image 22 that is superimposed on the viewing area 23. When the user 190 moves the HMD 110 worn on the head, the virtual camera 1 also moves in conjunction with the movement. As a result, the position of the visual recognition area 23 in the virtual space 2 changes. Thereby, the visual field image 26 displayed on the monitor 112 is updated to an image that is superimposed on the visual recognition area 23 in the virtual space 2 in the direction in which the user faces in the virtual space image 22. The user can visually recognize a desired direction in the virtual space 2.

  While wearing the HMD 110, the user 190 can visually recognize only the virtual space image 22 developed in the virtual space 2 without visually recognizing the real world. Therefore, the HMD system 100 can give the user a high sense of immersion in the virtual space 2.

  In one aspect, the processor 10 can move the virtual camera 1 in the virtual space 2 in conjunction with the movement of the user 190 wearing the HMD 110 in the real space. In this case, the processor 10 specifies an image area (that is, the visual recognition area 23 in the virtual space 2) projected on the monitor 112 of the HMD 110 based on the position and orientation of the virtual camera 1 in the virtual space 2.

  According to an embodiment, the virtual camera 1 preferably includes two virtual cameras, that is, a virtual camera for providing an image for the right eye and a virtual camera for providing an image for the left eye. Moreover, it is preferable that appropriate parallax is set in the two virtual cameras so that the user 190 can recognize the three-dimensional virtual space 2. In the present embodiment, the virtual camera 1 includes two virtual cameras, and the roll direction (w) generated by combining the roll directions of the two virtual cameras is adapted to the roll direction (w) of the HMD 110. The technical idea concerning this indication is illustrated as what is constituted.

[controller]
An example of the controller 160 will be described with reference to FIG. FIG. 10 is a diagram showing a schematic configuration of controller 160 according to an embodiment.

  As shown in FIG. 10, in one aspect, the controller 160 may include a right controller 800 and a left controller. The right controller 800 is operated with the right hand of the user 190. The left controller is operated with the left hand of the user 190. In one aspect, the right controller 800 and the left controller are configured symmetrically as separate devices. Therefore, the user 190 can freely move the right hand holding the right controller 800 and the left hand holding the left controller, respectively. In another aspect, the controller 160 may be an integrated controller that receives operations of both hands. Hereinafter, the right controller 800 will be described.

  The right controller 800 includes a grip 30, a frame 31, and a top surface 32. The grip 30 is configured to be held by the right hand of the user 190. For example, the grip 30 can be held by the palm of the right hand of the user 190 and three fingers (middle finger, ring finger, little finger).

  The grip 30 includes buttons 33 and 34 and a motion sensor 130. The button 33 is disposed on the side surface of the grip 30 and receives an operation with the middle finger of the right hand. The button 34 is disposed in front of the grip 30 and accepts an operation with the index finger of the right hand. In one aspect, the buttons 33 and 34 are configured as trigger buttons. The motion sensor 130 is built in the housing of the grip 30. Note that when the operation of the user 190 can be detected from around the user 190 by a camera or other device, the grip 30 may not include the motion sensor 130.

  The frame 31 includes a plurality of infrared LEDs 35 arranged along the circumferential direction. The infrared LED 35 emits infrared light in accordance with the progress of the program during the execution of the program using the controller 160. The infrared rays emitted from the infrared LED 35 can be used to detect the positions and postures (tilt and orientation) of the right controller 800 and the left controller (not shown). In the example shown in FIG. 10, the infrared LEDs 35 arranged in two rows are shown, but the number of arrangements is not limited to that shown in FIG. An array of one or more columns may be used.

  The top surface 32 includes buttons 36 and 37 and an analog stick 38. The buttons 36 and 37 are configured as push buttons. The buttons 36 and 37 receive an operation with the thumb of the right hand of the user 190. In one aspect, the analog stick 38 accepts an operation in an arbitrary direction of 360 degrees from the initial position (neutral position). The operation includes, for example, an operation for moving an object arranged in the virtual space 2.

  In one aspect, the right controller 800 and the left controller include a battery for driving the infrared LED 35 and other members. The battery includes, but is not limited to, a rechargeable type, a button type, a dry battery type, and the like. In another aspect, the right controller 800 and the left controller may be connected to a USB interface of the computer 200, for example. In this case, the right controller 800 and the left controller do not require batteries.

  FIG. 11 shows an example of a hand object 810 arranged in the virtual space corresponding to the right hand of the user 190 holding the right controller 800. For example, the yaw, roll, and pitch directions are defined for the hand object 810 corresponding to the right hand of the user 190. For example, when the input operation is performed on the button 34 of the right controller 800, the index finger of the hand object 810 is held, and when the input operation is not performed on the button 34, FIG. As shown, the index finger of the hand object 810 can be extended. For example, when the thumb and index finger are extended in the hand object 810, the direction in which the thumb extends is the yaw direction, and the direction in which the index finger extends is perpendicular to the plane defined by the roll direction, the yaw direction axis, and the roll direction axis. The direction is defined in the hand object 810 as a pitch direction.

[HMD control device]
With reference to FIG. 12, the control apparatus of HMD110 is demonstrated. In one embodiment, the control device is realized by a computer 200 having a known configuration. FIG. 12 is a block diagram showing a computer 200 according to an embodiment as a module configuration.

  As shown in FIG. 12, the computer 200 includes a display control module 220, an audio control module 225, a virtual space control module 230, a memory module 240, and a communication control module 250. The display control module 220 includes a virtual camera control module 221, a visual field region determination module 222, a visual field image generation module 223, and a reference visual line identification module 224 as submodules. The virtual space control module 230 includes a virtual space definition module 231, a virtual object generation module 232, a gaze detection module 233, an identification information control module 234, and a chat control module 235 as submodules.

  In an embodiment, the display control module 220, the audio control module 225, and the virtual space control module 230 are realized by the processor 10. In other embodiments, the plurality of processors 10 may operate as the display control module 220, the voice control module 225, or the virtual space control module 230, respectively. The memory module 240 is realized by the memory 11 or the storage 12. The communication control module 250 is realized by the communication interface 14.

  In one aspect, the display control module 220 controls image display on the monitor 112 of the HMD 110. The virtual camera control module 221 arranges the virtual camera 1 in the virtual space 2 and controls the behavior and orientation of the virtual camera 1. The visual field area determination module 222 defines the visual field area 23 according to the direction of the head of the user 190 wearing the HMD 110. The view image generation module 223 generates a view image to be displayed on the monitor 112 based on the determined viewing area 23. Further, the view image generation module 223 generates a view image based on the data received from the virtual space control module 230. The view image data generated by the view image generation module 223 is output to the HMD 110 by the communication control module 250. The reference line-of-sight identifying module 224 identifies the line of sight of the user 190 based on the signal from the gaze sensor 140.

  The voice control module 225 detects that a voice signal based on the utterance of the user 190 is input from the HMD 110 to the computer 200. The voice control module 225 attaches the input time to the voice signal corresponding to the utterance and generates voice data. The voice control module 225 transmits the voice data to the computer used by the user selected by the user 190 among the other computers 200A and 200B in a state where the computer 200 can communicate with the chat partner of the user 190.

  The virtual space control module 230 controls the virtual space 2 provided to the user 190. First, the virtual space definition module 231 defines the virtual space 2 in the HMD system 100 by generating virtual space data representing the virtual space 2.

  The virtual object generation module 232 generates data of objects arranged in the virtual space 2. For example, the virtual object generation module 232 generates avatar object data representing other users 190 </ b> A and 190 </ b> B who chat with the user 190 via the virtual space 2. Further, the virtual object generation module 232 may change the line of sight of the user's avatar object based on the line of sight detected in response to speech from other users 190A and 190B.

  The line-of-sight detection module 233 detects the line of sight of the user 190 based on the output from the gaze sensor 140. In one aspect, the line-of-sight detection module 233 detects the line of sight of the user 190 at that time based on the detection of the utterance by the user 190. The detection of the line of sight is realized by a known technique such as non-contact type eye tracking. As an example, like the scleral reflection method, the gaze sensor 140 applies the infrared rays to the eyes of the user 190, and based on the data obtained by photographing the reflected light with a camera (not shown), the gaze of the user 190 Motion can be detected. In one aspect, the line-of-sight detection module 233 specifies each position according to the movement of the line of sight of the user 190 as a coordinate value (x, y) based on one of the display areas of the monitor 112.

[Presentation of identification information]
The identification information control module 234 controls the presentation of the identification information of the avatar object presented in the virtual space 2. For example, in one aspect, the identification information control module 234 detects that the line of sight of the user 190 is directed to the avatar object presented in the virtual space 2 based on the output from the gaze sensor 140. The identification information control module 234 presents identification information of other users (for example, users 190A and 190B) corresponding to the avatar object. The identification information includes, for example, the name of the other user, the handle name, and other information that distinguishes it from other users.

  In one aspect, the identification information control module 234 presents the object so that the object representing the identification information faces the viewpoint of the user 190 independently of the orientation of the avatar object. For example, the identification information control module 234 outputs data for rendering the image representing the identification information so as to face the front of the user 190 on the monitor 112. The user 190 can easily know who is using the avatar object.

  In one aspect, the identification information control module 234 measures the time that has elapsed since the identification information was presented. When the elapsed time exceeds a predetermined time (for example, several seconds), the identification information control module 234 ends the presentation of the identification information. In this way, since the identification information recognized by the user 190 is not continuously presented in the virtual space 2, it is possible to prevent the other objects arranged in the virtual space 2 from becoming difficult to see.

  In one aspect, after the identification information of the other users 190A and 190B is erased, the identification information control module 234 determines that the line of sight of the user 190 is the avatar object of the other users 190A and 190B based on the output from the gaze sensor 140. It can be detected that the camera is turned again. In this case, the identification information control module 234 does not present the identification information of the other users 190A and 190B again. Since the user 190 has already recognized the other users 190 </ b> A and 190 </ b> B, the troublesomeness caused by the unnecessary identification information being presented again in the virtual space 2 can be prevented.

  In one aspect, the identification information control module 234 is different from the aspect of presenting the avatar object in which the identification information is not presented in the aspect of presentation of the avatar object in which the identification information of the other users 190A and 190B is already displayed. Then, it may be presented to the HMD 110. In this way, the user 190 can easily distinguish an avatar object for which identification information has already been presented from other avatar objects.

  In one aspect, the identification information control module 234 can detect the movement of the avatar object in the virtual space 2 based on a signal sent from the server 150. For example, the other users 190A and 190B may operate the right controller 800 to move their avatar objects. In such a case, the virtual object generation module 232 presents the avatar object at the destination location. The identification information control module 234 presents identification information in the vicinity of the moved avatar object. In this way, even if the location of the avatar object corresponding to each user in the virtual space 2 changes according to the operation of the other users 190A and 190B during the presentation of the identification information, each identification information is also in the vicinity of the avatar object. Presented to. The user 190 can accurately identify the other users 190A and 190B without overlooking the correspondence between the identification information and the avatar object.

  In one aspect, the identification information control module 234 detects that communication with the other user 190A or the user 190B has been interrupted based on a signal received from the server 150. The interruption may occur, for example, when the communication line is unstable, when radio waves used in the mobile communication network are interrupted, or when a power failure occurs. The identification information control module 234 may end the presentation of the avatar object and the identification information in response to the communication interruption. The identification information control module 234 may present the avatar object in the virtual space 2 when detecting that communication with the blocked other user is established again based on the signal received from the server 150.

  If the time from when the communication is interrupted until it is reestablished is less than a predetermined time, the identification information control module 234 may present the avatar object and the identification information again. When the communication is cut off in a state where the identification information is presented, when the cut-off time is short, the user 190 recognizes the avatar object and the identification information again, and then uses the other avatar object. Users can be made easy.

  On the other hand, when the time during which communication is interrupted becomes long, when the avatar object is presented again in the virtual space 2, the user 190 may not visually recognize the avatar object. In this case, when the user 190 visually recognizes the avatar object again, the identification information control module 234 can present the identification information again in the vicinity of the avatar object.

  In yet another aspect, the identification information control module 234 presents the identification information of the other users 190A and 190B to the virtual space 2 only when the other users 190A and 190B permit the presentation of the identification information. Also good. For example, in the user registration aspect of VR chat, each user who desires registration may set whether or not to disclose personal information. A user who does not wish to disclose personal information such as a real name, a photograph, or the like can register a setting for prohibiting the disclosure of the personal information in the server 150. In such a case, the user can enjoy VR chat with only the avatar object in the chat room without disclosing personal information. Therefore, when a specific user makes such a setting, the identification information control module 234 does not display the identification information even if the user 190 continues to see the avatar object.

  The chat control module 235 controls communication via the virtual space. In one aspect, the chat control module 235 reads out the chat application from the memory module 240 based on the operation of the user 190 or based on the chat start request transmitted by the other computer 200A, and passes through the virtual space 2. Communication started. When the user 190 inputs a user ID and password to the computer 200 and performs a login operation, the user 190 becomes one of the chat members via the virtual space 2 and participates in the chat session (also referred to as “room”). Associated. Thereafter, when the user 190A using the computer 200A logs in to the chat in the session, the user 190 and the user 190A are associated with each other as members of the chat. When the chat control module 235 recognizes the user 190A of the computer 200A that is the communication partner of the computer 200, the virtual object generation module 232 uses the object information 242 to generate data for presenting the avatar object corresponding to the user 190A. Generate the data and output the data to the HMD 110. When the HMD 110 displays the avatar object corresponding to the user 190 </ b> A on the monitor 112 based on the data, the user 190 wearing the HMD 110 recognizes the avatar object in the virtual space 2.

  In one embodiment, the chat control module 235 waits for input of voice data based on the utterance of the user 190 and input of data from the gaze sensor 140. When the user 190 performs an operation for selecting an avatar object in the virtual space 2 (for example, operation of a controller, gesture, selection by voice, gaze by line of sight, etc.), the chat control module 235 is based on the operation. , It is detected that a user (for example, user 190) corresponding to the avatar object is selected as a chat partner. When the chat control module 235 detects an utterance by the user 190, the chat control module 235, based on the network address of the computer 200A used by the user 190A, voice data based on a signal sent from the microphone 119 via the communication control module 250; The eye tracking data based on the signal sent from the gaze sensor 140 is transmitted to the computer 200A. Based on the eye tracking data, the computer 200A updates the line of sight of the user 190's avatar object, and transmits the audio data to the HMD 110A. When the computer 200A has a synchronization function, the change in the line of sight of the avatar object on the monitor 112 and the output of the sound from the speaker 115 are realized at substantially the same timing, so that the user 190A feels uncomfortable. It becomes difficult to feel.

  The memory module 240 holds data used for the computer 200 to provide the virtual space 2 to the user 190. In one aspect, the memory module 240 holds space information 241, object information 242, user information 243, and chat monitor information 244.

  The space information 241 holds one or more templates defined for providing the virtual space 2.

  The object information 242 includes data for displaying an avatar object used for communication via the virtual space 2, content reproduced in the virtual space 2, and information for arranging objects used in the content. keeping. The content may include, for example, content representing a scene similar to a game or a real society. The data for displaying the avatar object may include, for example, image data that schematically represents a communication partner with which a relationship has been established in advance as a chat partner, a photograph of the communication partner, and the like.

  The user information 243 includes a program for causing the computer 200 to function as a control device of the HMD system 100, an application program that uses each content held in the object information 242, a user ID required when executing the application program, I have a password etc. Data and programs stored in the memory module 240 are input by the user 190 of the HMD 110. Alternatively, the processor 10 downloads a program or data from a computer (for example, the server 150) operated by a provider that provides the content, and stores the downloaded program or data in the memory module 240.

  Chat monitor information 244 includes information on communication via virtual space 2 shared between computer 200 and other computers 200A and 200B. The chat monitor information 244 includes, for example, the identification information of each user participating in the chat using the virtual space 2, the login status of each user, the data for controlling whether or not the identification information can be presented, The date and time etc. presented in

  In one aspect, when each user logs in to a chat room prepared in advance for VR chatting, information of the logged-in user is transmitted to a computer used by another user who has logged in the chat room. For example, when the users 190A and 190B log in to the chat room, the user IDs, identification information, login status (eg, “login”) of the users 190A and 190B, and whether or not the identification information can be presented are determined from the computers 200A and 200B. To the computer 200.

  The communication control module 250 can communicate with the server 150 and other information communication devices via the network 19. The communication control module 250 is realized by a known communication technique such as a wired LAN or a wireless LAN.

  In an aspect, the display control module 220 and the virtual space control module 230 can be realized using, for example, Unity (registered trademark) provided by Unity Technologies. In another aspect, the display control module 220 and the virtual space control module 230 can also be realized as a combination of circuit elements that realize each process.

  Processing in the computer 200 is realized by hardware and software executed by the processor 10. Such software may be stored in advance in a memory module 240 such as a hard disk. The software may be stored in a CD-ROM or other non-volatile computer-readable data recording medium and distributed as a program product. Alternatively, the software may be provided as a program product that can be downloaded by an information provider connected to the Internet or other networks. Such software is read from a data recording medium by an optical disk drive or other data reader, or downloaded from the server 150 or other computer via the communication control module 250 and then temporarily stored in the storage module. . The software is read from the storage module by the processor 10 and stored in the RAM in the form of an executable program. The processor 10 executes the program.

  The hardware that constitutes the computer 200 is general. Therefore, it can be said that the most essential part according to the present embodiment is a program stored in the computer 200. Since the hardware operation of computer 200 is well known, detailed description will not be repeated.

  The data recording medium is not limited to a CD-ROM, FD (Flexible Disk), and hard disk, but is a magnetic tape, cassette tape, optical disk (MO (Magnetic Optical Disc) / MD (Mini Disc) / DVD (Digital Versatile Disc)). ), IC (Integrated Circuit) card (including memory card), optical card, mask ROM, EPROM (Electronically Programmable Read-Only Memory), EEPROM (Electronically Erasable Programmable Read-Only Memory), semiconductor memory such as flash ROM, etc. It may be a non-volatile data recording medium that carries a fixed program.

  The program here may include not only a program that can be directly executed by the processor 10, but also a program in a source program format, a compressed program, an encrypted program, and the like.

[Operation between computers by communication between two users]
Here, the operation of the computers 200 and 200A when the two users 190 and 190A communicate via the virtual space 2 will be described. Hereinafter, a case where the user 190A wearing the HMD 110A connected to the computer 200A speaks to the user 190 wearing the HMD 110 connected to the computer 200 will be described.

(Sender)
In one aspect, user 190A wearing HMD 110A speaks into microphone 119 in order to chat with user 190. The voice signal of the utterance is transmitted to the computer 200A connected to the HMD 110A. The voice control module 225 converts the voice signal into voice data and associates the voice data with a time stamp indicating when speech is detected. The time stamp is, for example, time data of an internal clock of the processor 10. In one aspect, time data when the audio signal is converted into audio data by the communication control module 250 is used as a time stamp.

  When the user 190A is speaking, the movement of the line of sight of the user 190A is detected by the gaze sensor 140. The detection result (eye tracking data) by the gaze sensor 140 is sent to the computer 200A. The line-of-sight detection module 233 specifies each position (for example, the position of the pupil) representing the change in the line of sight of the user 190A based on the detection result.

  The computer 200 </ b> A transmits audio data and eye tracking data to the computer 200. Audio data and eye tracking data are first sent to the server 150. The server 150 refers to the destination in each header of the audio data and the eye tracking data, and transmits the audio data and the eye tracking data to the computer 200. At this time, the timing at which the audio data reaches the computer 200 may not match the timing at which the eye tracking data reaches the computer 200.

(Receiver)
The computer 200 receives data transmitted by the computer 200A from the server 150. In one aspect, the processor 10 of the computer 200 detects that audio data has been received based on data sent from the communication control module 250. When the processor 10 identifies the voice data transmission source (that is, the computer 200 </ b> A), the processor 10 displays a chat screen on the monitor 112 of the HMD 110 as the chat control module 235.

  The processor 10 further detects that eye tracking data has been received. When the transmission source of eye tracking data (that is, the computer 200A) is specified, the processor 10 generates data for displaying the avatar object of the user 190A as the virtual object generation module 232.

  In another aspect, the processor 10 may receive eye tracking data prior to audio data. In this case, when detecting the transmission source identification number from the eye tracking data, the processor 10 determines that there is audio data transmitted corresponding to the eye tracking data. The processor 10 waits for output of data for displaying the avatar object until it receives audio data including the same transmission source identification number and time data as the transmission source identification number and time data included in the eye tracking data.

  In yet another aspect, the processor 10 may receive audio data prior to eye tracking data. In this case, when detecting the transmission source identification number from the audio data, the processor 10 determines that there is eye tracking data transmitted corresponding to the audio data. The processor 10 waits for output of audio data until it receives eye tracking data including the same transmission source identification number and time data as the transmission source identification number and time data included in the audio data.

  In each of the above aspects, the time data to be compared does not have to indicate the completely same time.

  When the processor 10 confirms the reception of the audio data and the eye tracking data including the same time data, the processor 10 outputs the audio data to the speaker 115 and monitors the data for displaying the avatar object in which the change based on the eye tracking data is reflected. To 112. As a result, since the user 190 can recognize the voice and the avatar uttered by the user 190A at the same timing, the user 190 does not feel a time lag due to a signal transmission delay (for example, a change in the timing of the avatar object and the voice output). Can enjoy chatting.

  Also, the processor 10 of the computer 200A used by the user 190A can synchronize the output timing of the audio data and the output timing of the avatar object reflecting the movement of the user's line of sight, as in the above-described processing. it can. As a result, the user 190A can also recognize the output of the voice uttered by the user 190 and the change of the avatar object at the same timing, so that the user can enjoy chatting without feeling a time lag due to a signal transmission delay.

<4. Control structure>
A control structure of the HMD system 100 will be described with reference to FIG. FIG. 13 is a sequence chart representing a part of processing executed in HMD system 100 according to an embodiment.

  In step S1510, the processor 10 of the computer 200 specifies virtual space image data as the virtual space definition module 231.

  In step S1520, processor 10 initializes virtual camera 1. For example, the processor 10 places the virtual camera 1 at a predetermined center point in the virtual space 2 and directs the line of sight of the virtual camera 1 in the direction in which the user 190 is facing.

  In step S <b> 1530, the processor 10 generates view image data for displaying an initial view image as the view image generation module 223. The generated view field image data is sent to the HMD 110 by the communication control module 250 via the view field image generation module 223.

  In step S1532, monitor 112 of HMD 110 displays a view field image based on the signal received from computer 200. The user 190 wearing the HMD 110 can recognize the virtual space 2 when viewing the visual field image.

  In step S <b> 1534, HMD sensor 120 detects the position and inclination of HMD 110 based on a plurality of infrared lights transmitted from HMD 110. The detection result is sent to the computer 200 as motion detection data.

  In step S1540, processor 10 identifies the viewing direction of user 190 wearing HMD 110 based on the position and inclination of HMD 110. The processor 10 executes the application program and displays objects in the virtual space 2 based on instructions included in the application program. The user 190 enjoys content that is visible in the virtual space 2 by executing the application program.

  In step S1542, the processor 10 updates the view image based on the determined state of the virtual user. The virtual user is, for example, a user wearing the HMD 110 connected to the computer 200 on which the processor 10 is mounted. Then, the processor 10 outputs data (view image data) for displaying the updated view image to the HMD 110.

  In step S1544, monitor 112 of HMD 110 updates the view image based on the received view image data, and displays the updated view image.

  In step S1550, controller 160 detects the operation of user 190. A signal indicating the detected operation is sent to the computer 200. In one embodiment, the signal includes an operation that causes the user 190 to change the position of the corresponding avatar in the virtual space. In another embodiment, the signal includes an operation for changing the position of the virtual camera 1 to which the view image provided to the user 190 corresponds.

  In step S1552, gaze sensor 140 detects the line of sight of user 190. A signal indicating the detected value for the detected line of sight is sent to the computer 200. In the present specification, placing a gazing point on an avatar is also treated as “designating an avatar”.

  That is, in the present embodiment, the computer 200 indicates that the user 190 has touched the avatar with a virtual hand by operating the controller 160 and / or that the gazing point of the user 190 has been placed on the avatar. It is treated that a virtual user has specified an avatar.

  In step S1554, processor 10 transmits to server 150 an input indicating that the virtual user has specified an avatar.

  The server 150 receives an input from the processor 10 of each computer 200 as to which user in the virtual space each virtual user has designated. Based on the fact that the input satisfies a predetermined condition, the server 150 matches two or more users among a plurality of users participating in the matching system. The server 150 transmits a predetermined instruction to the processor 10 of the computer 200 used by the matched user.

  In step S1560, processor 10 receives a predetermined instruction from server 150.

  In step S1570, processor 10 updates the view screen in accordance with an instruction from server 150, and outputs data (view image data) for displaying the updated view image to HMD 110.

  In step S1572, the monitor 112 of the HMD 110 updates the view image based on the received view image data, and displays the updated view image.

<5. Data structure>
The data structure of the memory module 240 will be described with reference to FIGS. 14 and 15. The chat monitor information shown in FIG. 14 and the object information shown in FIG. 15 may be stored in the chat information storage unit 512A of the server 150 by being transmitted from each computer 200 to the server 150 or the like.

[Chat monitor information]
FIG. 14 is a diagram illustrating an aspect of storing chat monitor information in memory module 240. In one aspect, the memory module 240 holds chat monitor information 244. Chat monitor information 244 includes a user ID 1610, a name 1620, a status 1630, a control flag 1640, and a presentation start date 1650.

  The user ID 1610 identifies users who share the virtual space 2. The name 1620 is used to notify each user who shares the virtual space 2. The name 1620 may be, for example, either the real name or the pen name of the user. The status 1630 represents a login state to the chat room where the user is established in the virtual space 2. The control flag 1640 controls whether or not the identification information (for example, real name, pen name, etc.) of the user is allowed to be presented to other users. The presentation start date and time 1650 represents the date and time when the identification information of the user was first presented in a session with a chat room established in the virtual space 2. In one aspect, the presentation start date and time 1650 is reset every time a chat session ends. Therefore, when the identification information presentation condition is satisfied again in the next session, the user who has already presented the identification information may be presented with the new identification information.

[Object information]
FIG. 15 is a diagram illustrating an aspect of storing object information in memory module 240. In one aspect, the memory module 240 holds object information 242. The object information 242 includes an object ID 1710, position information 1720, and a related user ID 1730.

  The object ID 1710 identifies each object placed in the chat room. For example, “screen” and “table” in FIG. 15 correspond to “object 1120” and “object 1110” in FIG. Each of “avatar (A)” and “avatar (B)” corresponds to an avatar object corresponding to each of the users 190A and 190B described with reference to FIG.

  The position information 1720 identifies the position of each object in the virtual space. In the example of FIG. 15, each of the position (1) to the position (4) represents, for example, three-dimensional coordinates in the virtual space.

<6. Change in relative position of virtual camera and object>
With reference to FIGS. 16 to 18, two modes in which the relative positions of the virtual camera and the object change will be described.

  FIG. 16 is a diagram for explaining a first aspect of a change in the relative position of the virtual camera and the object. In the first aspect, the position of the virtual camera 1 does not change, and the position of the object in the virtual space changes.

  More specifically, FIG. 16 shows two states 1601 and 1602 for the virtual space. States 1601, 1602 include objects 901, 1110, 1120 described in FIG.

  In the state 1601, the object 901 is located in the viewing area 23. On the other hand, in the state 1602, the object 901 is located outside the viewing area 23. That is, the position of the object 901 is changed in the virtual space between the state 1601 and the state 1602. Note that the position of the virtual camera 1 does not change between the state 1601 and the state 1602.

  1 corresponds to the visual recognition area 23 in the state 1601 in the virtual space image 22. The view image 1003 in FIG. 1 corresponds to the visual recognition area 23 in the state 1602 in the virtual space image 22.

  FIG. 17 is a diagram for explaining a second mode of change in the relative position of the virtual camera and the object. In the second mode, the position of the object in the virtual space does not change, and the position of the virtual camera 1 changes.

  FIG. 17 shows two states 1701 and 1702 for the virtual space. Between the states 1701 and 1702, the positions of the objects 901, 1110, and 1120 have not changed, but the position of the virtual camera 1 has changed. In the state 1701, the virtual camera 1 is located near the lower end of the virtual space image 22, whereas in the state 1702, the virtual camera 1 is located near the center of the virtual space image 22. As a result, the object 901 is located within the viewing area 23 in the state 1701, but is located outside the viewing area 23 in the state 1702.

  FIG. 18 is a diagram illustrating changes in the field-of-view image according to changes in the relative positions of the virtual camera 1 and the object 901 illustrated in FIG. FIG. 18 shows a view image 1101 corresponding to the state 1701 and a view image 1102 corresponding to the state 1702. The view image 1101 includes objects 901, 1110, and 1120. On the other hand, the field-of-view image 1102 includes the object 1120, but does not include the objects 901 and 1110.

  The change in the relative position between the virtual camera 1 and the object 901 in the virtual space has been described above with reference to FIGS. In the virtual space, the relative positions of the virtual camera 1 and the object 901 can be changed even when the positions of both the virtual camera 1 and the object 901 are changed.

<7. Generation of trajectory object>
The generation of the trajectory object 910 (FIG. 1) will be described with reference to FIGS.

  FIG. 19 is a diagram for explaining an example of a setting mode of the trajectory object 910. In FIG. 19, a virtual space image 501 represents a part of a virtual space image on the uv plane. The virtual space image 502 represents a part of the virtual space image on the uw plane. Each of the view images 511 and 512 represents a portion displayed as the view image in the virtual space images 501 and 502.

  In the virtual space images 501 and 502, the object 901 moves. The object 910X represents the position after the movement of the object 901.

  The computer 200 sets the movement path of the object 901 based on the positions before and after the movement of the object (objects 901 and 910X). In FIG. 19, examples of the movement route are shown as a movement route L21 in the virtual space image 501 and a movement route L22 in the virtual space image 502.

  As an example of the movement route, as shown as the movement route L21, the objects before and after the movement are connected by a straight line. In another example, as shown as the movement path L22, the positions of the objects before and after the movement are connected so as to avoid other objects (objects 1110 and 1120) in the view field image.

  The trajectory object 910 represents the movement of the object 901 to the position indicated by the object 910X, and includes at least a part of each of the movement paths L21 and L22. In one embodiment, the trajectory object 910 becomes wider in the direction intersecting the movement paths L21 and L22 as it is closer to the object 910X. In other words, the closer to the object 910X, the thicker it becomes. Thereby, the direction of movement is expressed more clearly.

  In an embodiment, the trajectory object 910 is set not to pass through the inside of the object 1110 as shown in the virtual space image 502. That is, the computer 200 sets the trajectory object 910 so as not to overlap the object 1110. When the trajectory object 910 is set so as to pass through the inside of the object 1110, it may give the user an unnatural feeling that the object 901 moves through the inside of the object 1110. By setting the trajectory object 910 to avoid the object 1110, it is possible to avoid giving such an unnatural feeling to the user.

  In an embodiment, as shown in the virtual space image 501, the computer 200 sets the trajectory object 910 so as not to overlap the object 1120. The view image 511 in the virtual space image 501 represents the view set for the avatar object corresponding to the user of the HMD 110 provided with the view image 511. By setting the trajectory object 910 so as not to overlap the object 1120, it is possible to avoid blocking the field of view of the avatar object to the object 1120.

  In other embodiments, the trajectory object 910 may overlap the object 1120 to some extent. For example, the computer 200 sets the trajectory object 910 so that the ratio of the surface of the object 1120 and the trajectory object 910 is less than a certain value (10%).

  FIG. 20 is a diagram for explaining another example of how the trajectory object 910 is set. In the example shown in FIG. 19, the trajectory object 910 is a hollow figure, whereas in the example shown in FIG. 20, the trajectory object 910 is shown as an arrow positioned on the movement paths L21 and L22. Yes. That is, the shape of the trajectory object 910 may be an arrow.

  Further, the trajectory object may be composed of a plurality of parts as shown in FIG. In FIG. 21, the trajectory object includes four portions of objects 910A, 910B, 910C, and 910D as shown in the virtual space images 501 and 502, respectively. The four portions of the objects 910A, 910B, 910C, and 910D may be displayed at the same time, or may be displayed sequentially (for example, in the order closer to the object 901).

  The trajectory object may be configured by the moving avatar object itself. That is, in an embodiment, each of the objects 910A, 910B, 910C, and 910D in FIG. 21 may have the same form as the object 901. Thereby, when the object 901 (avatar) moves from the position A to the position B (when the position of the object 901 and the position of the object 910X in FIG. 21 are specified by pinpoints), the computer 200 The object 901 is displayed in the virtual space so that the object 901 itself sequentially moves along the trajectory to the position B. Each of the objects 910A, 910B, 910C, and 910D in FIG. 21 may have a form in which the object 901 is enlarged or reduced.

<8. Process flow>
With reference to FIG. 22, processing executed to display a complementary image when the view field image is updated will be described. FIG. 22 is a flowchart of a process for displaying a complementary image executed by the processor 10. The process of FIG. 22 corresponds to the process of the subroutines of steps S1542 and S1570 of FIG. 13, and is realized by the processor 10 executing a given program, for example.

  In step S100, the processor 10 generates an updated view image based on the state of the virtual user (step S1542) or in response to an instruction from the server 150 (step S1570).

  In step S110, the processor 10 determines whether or not the update of the view field image is due to the movement of the virtual camera 1.

  For example, if the update of the view image in step S100 follows the change of the position of the virtual camera 1 as described with reference to FIG. 17, the update of the view image of the virtual camera 1 is performed. Judgment is due to movement. For example, the processor 10 determines the virtual position based on the position and inclination of the HMD 110 (step S1534 in FIG. 13), the operation on the controller 160 (S1550), and / or the line of sight of the user 190 detected by the gaze sensor 140 (S1552). The view image is updated to move the camera 1.

  The movement of the virtual camera 1 is an example of the movement of the avatar object corresponding to the virtual camera 1. In an embodiment, when the movement of the avatar object is instructed, the processor 10 moves the virtual camera according to the movement of the avatar object. Thereby, the view field image corresponding to the position after the movement of the avatar object is provided as the view field image.

  On the other hand, for example, if the update of the view image in step S100 follows the movement of the object as described with reference to FIG. 16, the update of the view image is based on the movement of the virtual camera 1. Judge that it is not. For example, when the processor 10 receives information representing the movement path of the object from the server 150 (step S1560 in FIG. 13), the processor 10 updates the view image in order to move the object in the virtual space.

  More specifically, for example, the user 190B operates the controller 160B to move an object corresponding to the user 190B. The controller 160B transmits a signal indicating the operation to the computer 200B. A signal indicating the operation is transmitted to the computer 200 via the computer 200B and the server 150. When the processor 10 of the computer 200 acquires the signal, the processor 10 updates the view image in order to move the object in the virtual space.

  If processor 10 determines in step S110 that the update of the view image is due to movement of virtual camera 1 (YES in step S110), control proceeds to step S170. Otherwise (NO in step S110), processor 10 advances the control to step S120.

  In step S120, the processor 10 acquires the position of each object in the updated view image. The position of each object is acquired by referring to object information (FIG. 15), for example.

  In step S130, the processor 10 sets the movement path of the object. For example, the movement route is set according to the mode shown in FIG.

  In step S140, the processor 10 generates a trajectory object. The generation of the trajectory object follows, for example, the mode shown in FIG. 19 or FIG.

  In step S150, processor 10 generates a complementary image. The complementary image is generated, for example, by combining the trajectory object generated in step S140 with the updated view image generated in step S100.

  In step S160, the processor 10 displays the complementary image generated in step S150 on the monitor 112. More specifically, data (view field image data) for displaying a complementary image is output to the HMD 110. An example of the complement image is the view image 1002 in FIG.

  In step S170, the processor 10 displays the field-of-view image updated in step S100 on the monitor 112. More specifically, data for displaying the updated view image (view image data) is output to the HMD 110. An example of the updated image is the view field image 1003 in FIG. Thereafter, the processor 10 ends the processing of FIG.

  According to the processing of FIG. 22 described above, when the view image is updated by the movement of the object in the virtual space, the processor 10 displays the complemented image on the monitor 112, and then displays the updated view image. indicate.

  The display of the complementary image is executed when the view field image is updated as the object moves in the virtual space, as described with reference to FIG. As described with reference to FIG. 17, when the view field image is updated by the movement of the virtual camera 1, the display of the complementary image may be omitted. This means that when the processor 10 determines in step S110 that the update of the view image is not due to the movement of the virtual camera 1 (NO in step S110), the control of steps S120 to S160 is executed, and step S110 is executed. When it is determined that the update of the view image is due to the movement of the virtual camera 1 (YES in step S110), this corresponds to the fact that the control in steps S120 to S160 is not executed.

<9. Summary of disclosure>
The present disclosure can be summarized as follows.

  (1) In the present disclosure, the computer 200A is connected to a plurality of head mounted devices (HMDs 110, 110A, 110B) directly or via the server 150. The method executed by the computer 200 to provide the virtual space includes the step of defining the virtual space (step S1510 in FIG. 13). As shown in FIG. 2 and the like, the method includes a first avatar object and a second head mounted device (HMD 110B) corresponding to a user of the first head mounted device (HMD 110A) among the plurality of head mounted devices. And placing a second avatar object (object 901) corresponding to the user in the virtual space. The method includes the step of presenting an image corresponding to the position of the first avatar object in the virtual space (view image 1001 in FIG. 1) to the first head mounted device. The method further includes a step of presenting a trajectory object (trajectory object 910) representing a movement path of the second avatar object to the first head mounted device based on an operation for moving the second avatar object ( Step S160).

  Note that some and all of the steps defined by the method of the present disclosure may be executed by a processor other than the processor 10 of the computer 200, such as the processor 151 of the server 150. That is, the processor 10 may be configured to present a view image transmitted from an external device without generating a view image.

  According to this indication, when the 2nd avatar object moves in virtual space, the locus object showing the movement course of the 2nd avatar object is displayed. Thereby, the user can predict the destination of the second avatar object by the trajectory object. Therefore, even when the position of the second avatar object changes rapidly in the virtual space, VR sickness in the user can be reduced.

  (2) In the above method, based on an operation for moving the first avatar object (an operation for moving the virtual camera 1), an image presented on the first head mounted device is displayed as the first avatar. A step of switching to an image corresponding to the position after the object has moved may be included (after step S110, executed without executing steps S120 to S160, step S170).

  (3) The virtual space may include other objects (object 1110) other than the first avatar object and the second avatar object. The trajectory object may be set to pass outside other objects (trajectory object 910 in the virtual space image 502).

  (4) The virtual space may include another object (object 1120) other than the first avatar object and the second avatar object. The trajectory object may be set such that the ratio of blocking the field of view from the first avatar object to another object is lower than a predetermined value (trajectory object 910 in the virtual space image 501).

  Each embodiment disclosed this time must be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims. In addition, the invention described in the embodiment and each modification is intended to be carried out independently or in combination as much as possible.

1 virtual camera, 2 virtual space, 5 reference line of sight, 10,151 processor, 11, 1
52 memory, 12 storage, 22, 22A, 22B, 501, 502 virtual space image, 23 viewing area, 190, 190A, 190B user, 200, 200A, 200
B computer, 511, 512, 1001, 1002, 1003 view image, 901
, 1110, 1120 objects.

Claims (6)

A method performed on a computer connected to a plurality of head mounted devices to provide a virtual space, comprising:
Defining a virtual space;
A first avatar object corresponding to a user of a first head mounted device and a second avatar object corresponding to a user of a second head mounted device among the plurality of head mounted devices are arranged in the virtual space. Steps,
Presenting an image corresponding to the position of the first avatar object in the virtual space to the first head mounted device;
Presenting a trajectory object representing a movement path of the second avatar object to the first head-mounted device based on an operation for moving the second avatar object.   Based on the operation for moving the first avatar object, the step of switching the image presented on the first head mounted device to an image corresponding to the position after the movement of the first avatar object is further performed. The method of claim 1 comprising. The virtual space includes objects other than the first avatar object and the second avatar object,
The method according to claim 1, wherein the trajectory object is set to pass outside the other object. The virtual space includes another object other than the first avatar object and the second avatar object,
The method according to any one of claims 1 to 3, wherein the trajectory object is set so that a ratio of blocking a field of view from the first avatar object to the another object is lower than a predetermined value. .   The program which makes a computer perform the method of any one of Claims 1-4. A memory storing the program according to claim 5;
An information processing apparatus comprising: a processor for executing the program.

Images